Chapter 11~ The Cell Cycle. 2007-2008 Biology is the only subject in which multiplication is the...

Chapter 11~ The Cell Cycle

2007-2008

Biology is the only subject in which multiplication is the same thing as division…

For reproduction For growth For repair & renewal

**To create TWO genetically IDENTICAL cells from ONE!**

Why do cells divide?

amoeba

Importance of Cell Division1. Growth and Development

2. Asexual Reproduction 3. Tissue Renewal

Zygote Embryo Fetus Adult1 Cell 100 cells millions cells 100 trillion cells

For both prokaryotes and eukaryotes...

Four events must occur for cell division:

a. Reproductive SIGNAL – initiates the process

b. Replication of DNA

c. Alignment of Replicated Chromosomes

d. Separation—separation of the DNA and cytoplasm to form two new genetically identical cells

Prokaryotic versus Eukaryotic Genetic Organization

Prokaryotic DNA

Prokaryotic versus Eukaryotic Genetic Organization

Eukaryotic DNA

Prokaryotic Genome Organization:

Nucleoid region Bacterial Chromosome

Single (1) circular DNA Small

(~1/100th human chromosome)

Plasmids – extra chromosomal DNA

Bacterial Fission

The Phases of a cell’s Life: Interphase (90% of

cycle) • G1 phase~ growth

• S phase~ synthesis of DNA

• G2 phase~ more growth

Mitotic phase • Mitosis~ nuclear

division • Cytokinesis~

cytoplasm division

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What are chromosomes?Tightly coiled pieces of DNA that contains the genes of every organism!!!

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Chromosome versus Chromatid A chromatid is one copy of a

chromosome; ONE replicated chromosome = TWO chromatids

Centromere holds chromatids together

double-strandedmitotic humanchromosomes

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Normal Karyotype (Fig 18.1)

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In humans...

How many chromosomes are present during G1?

How many chromosomes are present during G2?

How many chromatids are present during G2?

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46

46

92

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What is the difference between a haploid(n) and diploid (2n) cell?

Haploid cells have 1 set of chromosomes (n = 23 in humans)

Diploid cells have 2 sets of chromosomes (2n = 46 in humans) - one set from each parent

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Interphase

Growth (G1) Replication of

DNA (S) Preparation for

division (G2) Most of a cells life

cycle

Prophase

Chromosomes condense

Nuclear envelope breaks down

Mitotic spindle begins to form

In animal cells, centrioles divide

Prometaphase chromosomes

begin to migrate to cell equator

Spindles have been completely formed

Metaphase

Chromosomes are at metaphase plate

Spindle attaches to chromosomes at centromere

Anaphase

sister chromatids split apart at centromere

Migration of chromosomes to cell poles

Separation of chromatids

2 chromosomes1 chromosome2 chromatids

Telophase

Chromosomes decondense

Nuclear envelope reforms

Cytokinesis: cell membrane

divides

Mitosis in whitefish blastula

Mitosis in an animal cell

How does mitosis in plant and animal cells differ?

Cytokinesis Plant cells have

cell plate formation to help form the cell wall

Animal cells show “pinching in” of the cell membrane

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Spot the Phases: onion root tip

Any Questions??

Cell Cycle regulation

Checkpoints cell cycle controlled

by STOP & GO chemical signals at critical points

signals indicate if key cellular processes have been completed correctly

Checkpoint control system 3 major checkpoints:

G1/S can DNA synthesis begin?

G2/M has DNA synthesis been

completed correctly? commitment to mitosis

spindle checkpoint are all chromosomes

attached to spindle? can sister chromatids

separate correctly?

G1/S checkpoint G1/S checkpoint is most critical

primary decision point “restriction point”

if cell receives “GO” signal, it divides internal signals: cell growth (size), cell

nutrition external signals: “growth factors”

if cell does not receive signal, it exits cycle & switches to G0 phase

non-dividing, working state

“Go-ahead” signals

Protein signals that promote cell growth & division internal signals

“promoting factors” external signals

“growth factors” Primary mechanism of control

phosphorylation kinase enzymes either activates or inactivates cell signals

Cell cycle signals Cell cycle controls

cyclins regulatory proteins levels cycle in the cell

Cdks cyclin-dependent kinases phosphorylates cellular proteins

activates or inactivates proteins Cdk-cyclin complex

triggers passage through different stages of cell cycle

activated Cdk

inactivated Cdk

External signals Growth factors

coordination between cells protein signals released by

body cells that stimulate other cells to divide

density-dependent inhibition crowded cells stop dividing each cell binds a bit of growth

factor not enough activator left to

trigger division in any one cell anchorage dependence

to divide cells must be attached to a substrate

“touch sensor” receptors

Growth Factors and Cancer

Growth factors can create cancers proto-oncogenes

normally activates cell division growth factor genes become oncogenes (cancer-causing) when

mutated if switched “ON” can cause cancer example: RAS (activates cyclins)

tumor-suppressor genes normally inhibits cell division if switched “OFF” can cause cancer example: p53

Cancer & Cell Growth Cancer is essentially a failure

of cell division control unrestrained, uncontrolled cell growth

What control is lost? lose checkpoint stops gene p53 plays a key role in G1/S restriction

point p53 protein halts cell division if it detects damaged

DNA options:

stimulates repair enzymes to fix DNA forces cell into G0 resting stage keeps cell in G1 arrest causes apoptosis of damaged cell

ALL cancers have to shut down p53 activityp53 discovered at Stony Brook by Dr. Arnold Levine

p53 is theCell CycleEnforcer

DNA damage is causedby heat, radiation, or chemicals.

p53 allows cellswith repairedDNA to divide.

Step 1

DNA damage iscaused by heat,radiation, or chemicals.

Step 1 Step 2

Damaged cells continue to divide.If other damage accumulates, thecell can turn cancerous.

Step 3p53 triggers the destruction of cells damaged beyond repair.

ABNORMAL p53

NORMAL p53

abnormalp53 protein

cancercell

Step 3The p53 protein fails to stopcell division and repair DNA.Cell divides without repair todamaged DNA.

Cell division stops, and p53 triggers enzymes to repair damaged region.

Step 2

DNA repair enzymep53protein

p53protein

p53 — master regulator gene

Development of Cancer Cancer develops only after a cell

experiences ~6 key mutations (“hits”) unlimited growth

turn on growth promoter genes ignore checkpoints

turn off tumor suppressor genes (p53) escape apoptosis

turn off suicide genes immortality = unlimited divisions

turn on chromosome maintenance genes promotes blood vessel growth

turn on blood vessel growth genes overcome anchor & density dependence

turn off touch-sensor gene

It’s like anout-of-controlcar with manysystems failing!

What causes these “hits”? Mutations in cells can be triggered

by UV radiation chemical exposure radiation exposure heat

cigarette smoke pollution age genetics

Tumors Mass of abnormal cells

Benign tumor abnormal cells remain at original site as a

lump p53 has halted cell divisions

most do not cause serious problems &can be removed by surgery

Malignant tumor cells leave original site

lose attachment to nearby cells carried by blood & lymph system to other

tissues start more tumors = metastasis

impair functions of organs throughout body

Cancer: breast cancer cell & mammogram

Traditional treatments for cancers

Treatments target rapidly dividing cells high-energy radiation

kills rapidly dividing cells chemotherapy

stop DNA replication stop mitosis & cytokinesis stop blood vessel growth

New “miracle drugs” Drugs targeting proteins (enzymes)

found only in cancer cells Gleevec

treatment for adult leukemia (CML)& stomach cancer (GIST)

1st successful drug targeting only cancer cells

Novartes

withoutGleevec

withGleevec

2008-2009

Any Questions??